Details

Autor(en) / Beteiligte

• Keuter, Philipp
• Ravensburg, Anna L.
• Hans, Marcus
• Karimi Aghda, Soheil
• Holzapfel, Damian M.
• Primetzhofer, Daniel
• Schneider, Jochen M.

Titel

A Proposal for a Composite with Temperature-Independent Thermophysical Properties: HfV2–HfV2O7

Ist Teil von

• Materials, 2020-11, Vol.13 (21), p.5021

Ort / Verlag

Basel: MDPI AG

Erscheinungsjahr

2020

Quelle

Electronic Journals Library

Beschreibungen/Notizen

• The HfV2–HfV2O7 composite is proposed as a material with potentially temperature-independent thermophysical properties due to the combination of anomalously increasing thermoelastic constants of HfV2 with the negative thermal expansion of HfV2O7. Based on literature data, the coexistence of both a near-zero temperature coefficient of elasticity and a coefficient of thermal expansion is suggested for a composite with a phase fraction of approximately 30 vol.% HfV2 and 70 vol.% HfV2O7. To produce HfV2–HfV2O7 composites, two synthesis pathways were investigated: (1) annealing of sputtered HfV2 films in air to form HfV2O7 oxide on the surface and (2) sputtering of HfV2O7/HfV2 bilayers. The high oxygen mobility in HfV2 is suggested to inhibit the formation of crystalline HfV2–HfV2O7 composites by annealing HfV2 in air due to oxygen-incorporation-induced amorphization of HfV2. Reducing the formation temperature of crystalline HfV2O7 from 550 °C, as obtained upon annealing, to 300 °C using reactive sputtering enables the synthesis of crystalline bilayered HfV2–HfV2O7.